Oxygen deprivation within tumors is one of the most prevalent causes of resilient cancer cell survival and increased immune evasion in breast cancer (BCa). Current in vitro models do not adequately mimic physiological oxygen levels relevant to breast tissue and its tumor-immune interactions. In this study, we propose an approach to engineer a three-dimensional (3D) model (named 3D engineered oxygen, 3D-O) that supports the growth of BCa cells and generates physio-and pathophysiological oxygen levels to understand the role of oxygen availability in tumor-immune interactions. BCa cells (MDA-MB-231 and MCF-7) were embedded into plasma-derived 3D-O scaffolds that reflected physio-and pathophysiological oxygen levels relevant to the healthy and cancerous breast tissue. BCa cells grown within 3D-O scaffolds were analyzed by flow cytometry, confocal imaging, immunohistochemistry/immunofluorescence for cell proliferation, extracellular matrix protein expression, and alterations in immune evasive outcomes. Exosome secretion from 3D-O scaffolds were evaluated using the NanoSight particle analyzer. Peripheral blood mononuclear cells were incorporated on the top of 3D-O scaffolds and the difference in tumor-infiltrating capabilities as a result of different oxygen content were assessed by flow cytometry and confocal imaging. Lastly, hypoxia and Programmed death-ligand 1 (PD-L1) inhibition were validated as targets to sensitize BCa cells in order to overcome immune evasion. Low oxygen-induced adaptations within 3D-O scaffolds validated known tumor hypoxia characteristics such as reduced BCa cell proliferation, increased extracellular matrix protein expression, increased extracellular vesicle secretion and enhanced immune surface marker expression on BCa cells. We further demonstrated that low oxygen in 3D-O scaffolds significantly influence immune infiltration. CD8+ T cell infiltration was impaired under pathophysiological oxygen levels and we were also able to establish that hypoxia and PD-L1 inhibition re-sensitized BCa cells to cytotoxic CD8+ T cells. Bioengineering the oxygen-deprived BCa tumor microenvironment in our engineered 3D-O physiological and tumorous
Oxygen deprivation within tumors is one of the most prevalent causes of resilient cancer cell survival and increased immune evasion in breast cancer (BCa). Current in vitro models do not adequately mimic physiological oxygen levels relevant to breast tissue and its tumor-immune interactions. Here, we propose an approach to engineer a three-dimensional (3D) model (named 3D engineered oxygen, 3D-O) that supports growth of BCa cells and generates physio-and pathophysiological oxygen levels. Low oxygen-induced changes within the 3D-O model supported known tumor hypoxia characteristics such as reduced BCa cell proliferation, increased extracellular matrix protein expression, increased extracellular vesicle secretion and enhanced immune surface marker expression on BCa cells. We further demonstrated that low oxygeninduced changes mimicked tumor-immune interactions leading to immune evasion mechanisms. CD8+ T cell infiltration was significantly impaired under pathophysiological oxygen levels andwe were able to establish that hypoxia inhibition re-sensitize BCa cells to cytotoxic CD8+ T cells.Therefore, our novel 3D-O model could serve as a promising platform for the evaluation of immunological events and as a drug-screening platform tool to overcome hypoxia-driven immune evasion.
Outcomes have not improved for metastatic osteosarcoma for several decades. In part, this failure to develop better therapies stems from a lack of understanding of osteosarcoma biology, given the rarity of the disease and the high genetic heterogeneity at the time of diagnosis. We report here the successful establishment of a new human osteosarcoma cell line, COS-33, from a patient-derived xenograft and demonstrate retention of the biological features of the original tumor. We found high mTOR signaling activity in the cultured cells, which were sensitive to a small molecule inhibitor, rapamycin, a suppressor of the mTOR pathway. Suppressed mTOR signaling after treatment with rapamycin was confirmed by decreased phosphorylation of the S6 ribosomal protein. Increasing concentrations of rapamycin progressively inhibited cell proliferation in vitro. We observed significant inhibitory effects of the drug on cell migration, invasion, and colony formation in the cultured cells. Furthermore, we found that only a strong osteogenic inducer, bone morphogenetic protein-2, promoted the cells to differentiate into mature mineralizing osteoblasts, indicating that the COS-33 cell line may have impaired osteoblast differentiation. Grafted COS-33 cells exhibited features typical of osteosarcoma, such as production of osteoid and tumorigenicity in vivo. In addition, we revealed that the COS-33 cell line retained a complex karyotype, a homozygous deletion of the TP53 gene, and typical histological features from its original tumor. Our novel cellular model may provide a valuable platform for studying the etiology and molecular pathogenesis of osteosarcoma as well as for testing novel drugs for future genome-informed targeted therapy.
The diverse epithelial cell types of the kidneys are segregated into nephron segments and the collecting ducts in order to endow each tubular segment with unique functions. The rich diversity of the epithelial cell types is highlighted by the unique membrane channels and receptors expressed within each nephron segment. Our previous work identified a critical role for Myh9 and Myh10 in mammalian endocytosis. Here, we examined the expression patterns of Nonmuscle myosin 2 (NM2) heavy chains encoded by Myh9, Myh10, and Myh14 in mouse kidneys as these genes may confer unique nephron segment‐specific membrane transport properties. Interestingly, we found that each segment of the renal tubules predominately expressed only two of the three NM2 isoforms, with isoform‐specific subcellular localization, and different levels of expression within a nephron segment. Additionally, we identify Myh14 to be restricted to the intercalated cells and Myh10 to be restricted to the principal cells within the collecting ducts and connecting segments. We speculate that the distinct expression pattern of the NM2 proteins likely reflects the diversity of the intracellular trafficking machinery present within the different renal tubular epithelial segments.
Drug-infusion balloons are one of the currently used local drug delivery devices for preventing restenosis after endovascular treatments. An antiproliferative drug (paclitaxel, PAT) is infused through the balloon using a cremophor-based formulation to control restenosis. However, the major limitations of this approach are poor in vivo drug uptake and a limit in the amount of PAT delivered because of cremophor toxicity. In this study, we have investigated the use of different excipients for effectively infusing PAT out of the balloon for improved drug uptake in the tissue. The excipients include nanoparticle albumin-bound PAT (nab-PAT, a nanobiomaterial used in cancer therapy), urea (a hydrophilic agent used for faster drug transfer), iodixanol (a contrast agent used for coronary angiography), and cremophor-PAT (the most commonly used PAT formulation). An in vitro drug release, smooth muscle cell (SMC) response, endothelial cell (EC) response, and in vivo drug uptake were investigated for all the different excipients of PAT infused through the balloon. The nab-PAT was as effective as cremophor in infusing out of the balloon and inhibiting SMC growth. Also, nab-PAT showed a significantly greater amount of in vivo PAT uptake than that of cremophor-PAT. Urea and iodixanol were not effective in delivering a clinically relevant dose of PAT due to the poor solubility of PAT in these excipients. Urea eradicated all the SMCs and ECs, suggesting a toxic effect, which impedes its use in balloon-based therapy. Thus, this study demonstrated that nab-PAT is an effective formulation to locally deliver PAT through infusion balloons. © 2015 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 105B: 376-390, 2017.
In developing tissues, knowing the localization and interactors of proteins of interest is key to understanding their function. Here, we describe the Breasi-CRISPR approach (Brain Easi-CRISPR), combining Easi-CRISPR with in utero electroporation to tag endogenous proteins within embryonic mouse brains. Breasi-CRISPR enables knock-in of both short and long epitope tag sequences with high efficiency. We visualized epitope tagged proteins with varied expression levels, such as ACTB, LMNB1, EMD, FMRP, NOTCH1, and RPL22. Detection was possible by immunohistochemistry as soon as one day after electroporation and we observed efficient gene editing in up to 50% of electroporated cells. Moreover, tagged proteins could be detected by immunoblotting in lysates from individual cortices. Next, we demonstrated that Breasi-CRISPR enables the tagging of proteins with fluorophores, allowing the visualization of endogenous sproteins via live-imaging in organotypic brain slices. Finally, we used Breasi-CRISPR to perform co-IP mass-spectrometry analyses of autism-related protein FMRP to discover its interactome in the embryonic cortex. Together, these data show Breasi-CRISPR is a powerful tool with diverse applications that will propel the understanding of protein function in neurodevelopment.
In developing tissues, knowing the localization and interactors of proteins of interest is key to understanding their function. This can be challenging when the researched protein lacks reliable antibodies. Here, we combine Easi-CRISPR with in utero electroporation to tag endogenous proteins within embryonic mouse brains. This method is called Breasi-CRISPR (Brain Easi-CRISPR), and enables knock-in of both short and long epitope tag sequences in genes of interest with high efficiency. Using Breasi-CRISPR, we were able to visualize epitope tagged proteins known to have either high or low expression levels, such as ACTB, LMNB1, EMD, FMRP, NOTCH1, and RPL22. Detection was possible by immunohistochemistry as soon as one day after electroporation at embryonic day 13 (E13). Two and five days after electroporation, we observed efficient gene editing in up to 50% of electroporated cells. Moreover, tagged proteins could be detected by immunoblotting in lysates from individual cortices two days after electroporation. Next, we demonstrated that Breasi-CRISPR enables the tagging of proteins with fluorophores in an efficient manner, allowing the visualization of endogenous proteins via live-imaging in organotypic brain slices two days after electroporation. Finally, we used Breasi-CRISPR to perform co-IP mass-spectrometry analyses of tagged autism-related protein FMRP to discover its interactome in the embryonic cortex. Together, these data show Breasi-CRISPR is a powerful tool with diverse applications that will propel the understanding of protein function in neurodevelopment.
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